High-Throughput Computational Screening of thermal conductivity, Debye temperature and Grüneisen parameter using a quasi-harmonic Debye Model (1407.7789v3)

Abstract: The quasi-harmonic Debye approximation has been implemented within the AFLOW and Materials Project frameworks for high-throughput computational science (Automatic Gibbs Library, AGL), in order to calculate thermal properties such as the Debye temperature and the thermal conductivity of materials. We demonstrate that the AGL method, which is significantly cheaper computationally compared to the fully ab initio approach, can reliably predict the ordinal ranking of the thermal conductivity for several different classes of semiconductor materials. We also find that for the set of 182 materials investigated in this work the Debye temperature, calculated with the AGL, is often a better predictor of the ordinal ranking of the experimental thermal conductivities than the calculated thermal conductivity. The Debye temperature is thus a potential descriptor for high-throughput screening of the thermal properties of materials.

High-Throughput Computational Screening of Thermal Properties Using a Quasi-Harmonic Debye Model

The paper presents the implementation of a quasi-harmonic Debye model to calculate the thermal properties of materials, specifically focusing on the Debye temperature, thermal conductivity, and Grüneisen parameter, within the frameworks of AFLOW and the Materials Project. This implementation is aimed at establishing a high-throughput computational approach for materials science that effectively identifies potential candidates with desirable thermal properties, particularly high thermal conductivity materials.

Methodological Framework

The approach utilizes a quasi-harmonic approximation where the Gibbs free energy, a state function integral to thermodynamics, is minimized to predict equilibrium states as a function of pressure, temperature, and volume. The model efficiently predicts vibrational contributions to free energy without the need for computationally expensive anharmonic calculations. The main advantage of this approach is its reduced computational cost compared to fully ab initio methods, making it feasible for massive datasets.

The work is anchored on the use of density functional theory (DFT) through the VASP software, ensuring the electronic structure is accurately accounted for. Subsequently, a series of isotropic volume expansions are used to fit energy against volume, from which important thermodynamic derivatives such as the bulk modulus and Debye temperature are derived. The simplicity of this model facilitates high-throughput screenings across a wide variety of materials, from simple binary compounds to more complex half-Heusler structures.

Results and Correlations

Data were compiled for 75 materials across different crystallographic symmetries, including zincblende, diamond, rocksalt, and wurzite structures, as well as rhombohedral, body-centered tetragonal, and various other miscellaneous structures. The results show commendable Pearson correlations between calculated thermal conductivities and experimental data, with especially high values observed in high-symmetry materials. This suggests that despite the Debye model's known limitations, it remains effective for ranking materials by thermal conductivity.

A significant finding is the utility of the Debye temperature as a descriptor for thermal conductivity prediction, with strong correlations indicating its robustness in screening applications. However, the Grüneisen parameter exhibited weaker correlations with experimental data, highlighting areas where the model could be refined or complemented with additional methodological vectors.

In the examination of half-Heusler materials, results from the quasi-harmonic Debye model were compared to machine learning predictions and full phonon calculations. The model, although it showed lower correlations compared to experimental validations, still provided valuable first-order insights into the thermal properties of numerous unexplored materials.

Implications and Future Directions

The implications of this research lie in its contribution to computational methods in materials science, particularly its demonstration that high-throughput techniques can provide reliable indicators for material screening. The ability of the Debye model to predict ranking effectively positions it as a viable tool within broader computational pipelines for identifying potential high-performance materials for industrial applications.

Potential future developments from this research could involve integrating more comprehensive anharmonic corrections to refine predictions further and exploring hybrid models that leverage machine learning outputs for validation and correction of theoretical models. Additionally, extending the database to include amorphous and highly anisotropic materials could broaden the model's applicability.

In conclusion, this research underscores the practicality and efficacy of using simplified harmonic approximations for large-scale screening by providing sufficient predictive power to guide experimental pursuits—bridging computational exploration with empirical validation in the field of materials thermodynamics.